Method and apparatus for repair of wells utilizing meltable repair materials and exothermic reactants as heating agents

ABSTRACT

A method and apparatus are described for creating a fluid seal in a subterranean well structure having a fluid seal defect. The method comprises introducing a meltable repair material proximate a structure in a subterranean well which has a fluid seal defect or enhanced seal capacity is required or it is desired to temporarily or permanently hydraulically isolate a portion the well or strengthen the structural integrity of well tubulars or tubular hangers. Exothermic reactant materials are located proximate the meltable repair material. The exothermic reactant material is ignited or an exothermic reaction otherwise initiated which supplies heat to and melts the meltable repair material into a molten mass. The molten mass flows and solidifies across the structure and the fluid seal defect to effect a fluid seal in the subterranean well structure or the structural integrity is enhanced. Examples of preferred exothermic reactant materials include thermite, thermate, fusible chemical reactants such as ammonium chloride and sodium nitrate, and oxidizers and accompanying hydrocarbon based fuels. Examples of preferred meltable repair materials include solder or brazing materials and eutectic metals which expand upon cooling and solidifying from a molten state.

TECHNICAL FIELD

The present invention relates generally to the repair of gas and oil wells, and more particularly, to those repairs which utilize eutectic metal plugs to seal existing leaks or to form temporary or permanent plugs for the purpose of isolating pressure within a portion of a well.

BACKGROUND OF THE INVENTION

During the life of a well, it is often necessary to isolate parts for the well to 1) shut off unwanted production of water or gas, 2) prevent communication of pressure to surface through annular communication, or 3) isolate portions of the well from acid or hydraulic stimulation to facilitate selective stimulation. Examples of structures having fluid seal defects needing repair may include leaking cemented annuli, leaking plugs such as cement and mechanical plugs, leaking abandoned or unwanted water or gas producing perforations, high pressure intervals which are to be temporarily or permanently isolated and gravel-packed production intervals which are to be shut-off from water influx.

Metal seals or plugs which are melted and then solidified in place are known to be used to effect fluid seals or plugs in defective structures in wells. For example, U.S. Pat. No. 6,474,414, to Gonzalez et al., entitled “Plug for Tubulars”, describes the use of a molten metal plug which expands upon solidification to form a pressure resistant seal in a tubular such as is used in oil and gas exploration and production. The disclosure of U.S. Pat. No. 6,474,414 is hereby incorporated by reference in its entirety.

The Gonzalez et al. patent describes how eutectic metals are heated until molten and then the molten eutectic metal is introduced into confined regions of downhole structures requiring fluid sealing. The molten eutectic metal solidifies in the confined region forming a sealing plug with the structure. Because eutectic metals are preferably selected which expand upon cooling and solidifying, the sealing plugs ideally form pressure resistant seals with the cooperating structures.

As examples, the Gonzalez et al. patent describes a plug which is placed into a structure, i.e., a standard pipe connection, including a collar which uses a threaded connection to secure two joints of tubing together. A solidified eutectic plug is formed proximate the ends of the joints and within the collar. In another embodiment, the sealing of perforations in a tubing is taught. Further, another example is the repair of a defective cemented interval which was intended to seal an annulus between a tubing and casing string.

The Gonzalez et al. patent describes the use of electrical heaters to provide heat to melt the eutectic metal in a well. Use of such devices which require substantial amounts of electrical power to operate have disadvantages such as the need for power generating units, long, heavy electrical cables, and significant excess electrical capacity, particularly on off-shore structures where weight and space are at a premium. Improved methods and apparatus for heating meltable repair materials to be used in downhole well repairs and environments are needed.

SUMMARY OF THE INVENTION

A method and apparatus are described for effecting a fluid seal in a subterranean well structure. The method comprises introducing a meltable repair material proximate a structure in a subterranean well where a fluid seal is desired. Exothermic reactant materials are located proximate the meltable repair material. The exothermic reactant is ignited or otherwise initiated to create an exothermic reaction which supplies heat to and melts the meltable repair material into a molten mass. The molten mass flows and solidifies across the structure and the fluid seal defect to effect a fluid seal in the subterranean well structure. Examples of preferred exothermic reactant materials include thermite, thermate and highly exothermic chemical reactions such as the reaction between ammonium chloride and sodium nitrite. Examples of preferred meltable repair materials include solder and eutectic metals which expand upon cooling and solidifying from a molten state Also, the exothermic reactant materials may include oxidizers and separate fuels which can be combined and ignited to provide an exothermic reaction to melt the meltable repair material.

A repair tool for effecting a fluid seal in a subterranean well structure having a fluid seal defect is also disclosed. A housing contains a meltable repair material and an exothermic reactant material proximate the meltable repair material. The repair tool may be introduced into a well and proximate a structure having a fluid seal defect. The exothermic reactant materials may be ignited to melt the meltable repair material into a flowable molten mass. The molten mass can then be discharged from the housing to cool and solidify upon the structure to effect a fluid seal repair or establish an isolating plug.

It is an object of the present invention to melt a meltable repair material, such as a eutectic metal, utilizing an exothermic reactant material, such as thermite or thermate, to create a molten mass of material which can flow upon and seal with a subterranean well structure to effect a fluid seal repair or pressure isolation plug, preferable a seal which is a press-fit and is pressure resistant.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other objects, features and advantages of the present invention will become better understood with regard to the following description, pending claims and accompanying drawings where:

FIG. 1 is a schematic drawing of an exothermic heating apparatus disposed within eutectic metal pellets located within a well above a cement or mechanical bridge plug or float shoe and located within the well in an area where an extreme pressure isolation bridge plug is desired or a pressure communication defect exists;

FIG. 2 is a schematic drawing of a repaired well wherein the eutectic metal pellets have been melted and resolidified forming a press-fit plug more capably sealing the cement or mechanical bridge plug and any perforations or leaks in the tubing or casing;

FIG. 3 is a schematic drawing of a repair tool located in a wellbore above a cement or mechanical bridge plug and adjacent tubing which is to be repaired by forming a eutectic metal plug;

FIG. 4 is a schematic drawing of the exothermic heating apparatus which can be located adjacent eutectic metal pellets disposed at the bottom of a well, in an inner annulus or in an outer annulus of a well wherein the pellets can be melted and resolidified to form pressure-fit seals in the wellbore to prevent communication of pressure to surface;

FIG. 5 is a schematic drawing of another embodiment of a repair tool disposed in a wellbore which can provide its own support platform for placing and supporting a solidified plug in a casing; and

FIG. 6 is a schematic drawing of the repair tool of FIG. 5 after being deployed to create a press-fit seal with the casing.

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides apparatus and methods for repairing fluid seal defects in subterranean structures of wells using meltable repair materials which are melted using exothermic reactant materials. By way of example and not limitation, the method and apparatus can be used to repair leaking cemented annuli, cement, mechanical or other fluid sealing plugs, unwanted perforations in wells which are to be abandoned or to temporarily or permanently isolate high pressure intervals, or shut-off water influx in gravel-packed production intervals. Defects may include seals, while currently integral, are to be reinforced to further enhance the structural integrity of the seal.

As a first example, FIG. 1 shows a casing 20 lining a wellbore 22 formed in an earth formation 24. Located within casing 20 is a cement or mechanical bridge plug 26. Cracks 30 in cement plug 26 and perforations 32 in casing 20 allow fluids to pass through cement plug 26 and casing 20 or the plug may need additional isolation potential or mechanical integrity to prevent future leaks. Plug 30 could be a mechanical bridge plug, a sand plug, a lead shot plug and/or an accumulation of metal particulate piled atop the bottom of wellbore 22 or set higher in well bore to temporarily or permanently isolate the interval below or effect seal repair at the chosen setting depth. Perforations 32 may have been created to provide a pathway to a producing formation which is now to be abandoned. Or else perforations 32 may be caused by stress fracturing and corrosion. In any event, these cracks 30 and perforations 32 are now defects in the corresponding structures and need to be sealed to fluidly isolate the inside of casing 20 from the wellbore beneath the cement plug 26 and from the wellbore outside casing 20.

An exothermic heating apparatus 34 is lowered down wellbore 22 until it is near cement plug 26 and perforations 32 in casing 20. Exothermic heating apparatus 34 comprises exothermic reactant materials 36, preferably in solidified block form, an igniter 40 and a support line 42 for suspending and locating exothermic heating apparatus 34 in wellbore 20. Preferably, igniter 40 is embedded within or adjacent to the exothermic reactant materials 36. Support line 42 may be tubing or simply a wireline or e-line if venting of the reaction is not needed. An electrical conduit 44 may be included with support line 42 to provide power to igniter 40. Alternatively, igniter 40 any other type of igniter used to ignite or initiate the exothermic reaction such as percussion type igniter activated by a falling bar or other object.

Exothermic reactant material 36 is made of a material which ideally provides a large quantity of heat when ignited. Preferably, exothermic block 36 is made of a thermite material, and most preferably, is thermate which can be ignited and burns even in water. One example of an exothermic thermite material is a granulated and cast mixture of aluminum particles with iron oxide. Also a bonding agent may be added to the thermite such as starch. Exothermic reactant material 36 is sacrificial in that it is a combustible material which sustains a slow burn for a required interval. For instance, the exothermic block may be poured with suitable inhibitors and binding agents so that it burns at 5,000 degrees F. for sufficient time to heat meltable repair materials until molten. The molten repair materials may then be cooled and used to plug fractures, perforations or other failures and defects in the downhole structures of well 18 or to enhance the seal and structural integrity of existing bridge plugs, packer sealing elements or liner hangers within the well bore.

Other exothermic reactant materials may also be used with this invention. For example, Nguyen, Duc A., in a PhD dissertation entitled, “Fused Chemical Reactions to Remediate Paraffin Plugging in Sub-Sea Pipelines”, University of Michigan (2004) teaches the benefits of using ammonium chloride and sodium nitrite as reactants to create large quantities of exothermic heat. Fused chemical reactions are reactions that can be delayed by physical or chemical means. The controlled-release of an exothermic reaction can obtained by putting a polymeric, paraffin, or resin coating on an acid catalyst in a mixture of aqueous NH₄CL and NaNO₂ reactants. Preferred acid catalysts include common mineral acids like hydrochloric, sulfuric, and nitric, and organic acids like formic, acetic, citric, benzoic, sulfamic, etc. The acid catalyst could be released down the tubing and into the mixture of reactants to initiate an exothermic reaction. As the polymer, paraffin, or resin coating dissolves in the mixture due to temperature or solvent action, the encapsulated acid catalysts are released and an exothermic reaction is initiated.

After exothermic reactant material 36 is properly positioned, pellets 38 of the meltable repair material are introduced into casing 20 covering exothermic heating apparatus 34. Most preferably, the meltable repair materials are made of eutectic metals which expand upon solidifying from a molten mass. While pellets 38 are preferred, the meltable repair materials may be provided in other forms such as in a solid and annular block form. Meltable repair materials suitable for use in this embodiment of the invention generally include most any material that will solidify under locally ambient conditions and form a plug having sufficient strength and bond to withstand the pressure differential across the plug. Preferably, the plug forms a tight mechanical pressure seal. This can be accomplished by either or both of selecting a molten mass of metal which expands as it solidifies and/or heating the tubing sufficiently so that it will diametrically shrink adequately to form the tight mechanical pressure seal as it cools. The former can be facilitated by selecting a soldering composition which contains least 10 parts per hundred, preferably at least 30 parts per hundred, and most preferably, at least 50 parts per hundred, of Bismuth. The second can be facilitated by heating the tubing to relatively high temperatures, such as in the range of 300-1100 F, and, if desired, employing a brazing or soldering composition to form the plug. The process may also be enhanced by incorporating a chemical flux borax or acid to improve adhesion of the solder or brazing material.

For downhole applications, locally ambient temperatures can range from about 40 to about 1,000 F (or higher, but such temperatures are not compatible with desirable liquid hydrocarbon products). Generally, downhole temperatures will range from about 32 F to about 700 F and will often be in the range of from about 100 F to about 300 F. Locally ambient pressures can range from 14.7 psi to 20,000 psi (or higher), but will generally range from about 14.7 to 15,000 psi and are usually in the range of from 14.7 to 10,000 psi.

Suitable materials will generally comprise a high percentage, generally in excess of 90% by weight of metals and will exhibit a melting point of less than 1100 F, generally in the range of 100 to 300 F. Generally speaking, it is preferable that the materials be relatively soft, so that they can be easily drilled out if necessary. Soldering compositions are generally suitable for most applications. Most suitable soldering compositions are metal alloys. As noted above, it is also desirable to have materials that expand when changing from a molten state to a solid state.

Preferred solders for use at ambient temperatures in the range of 150-600 F can comprise chiefly bismuth with optional lead, tin, cadium, antimony, and silver. Some examples from the Handbook of Chemistry and Physics, 54th edition, 1973-1974 (CRC Press, Cleveland, Ohio) include:

25 Pb/25 Sn/50 Bi (266 F liquidus temperature),

25 Pb/50 Sn/25 Bi (336 F liquidus temperature)

50 Pb/37.5 Sn/12.5 Bi (374 F liquidus temperature)

60 Pb/40 Sn (460 F/361 F liquidus/solidus temps) (AWS-ASTM classification 40A)

85 Pb/15 Sn (550 F/440 F liquidus/solidus temps) (AWS-ASTM classification 15B)

97.5 Pb/2.3-2.7 Ag (588 F/588 F liquidus/solidus temps) (AWS-ASTM classification

1.5S)

In the table just given, constituents present at less than 1 part per hundred are not listed.

For applications in the 600-1000 F range, preferred solders comprise chiefly aluminum or magnesium-containing brazing materials: Examples (from CRC) include:

11.0-13.0 Al/4.5-5.5 Zn/bal. Mg.

(liquidus/solidus temps 1050/770 F) (AWS-ASTM classification 1.5S)

8.3-9.3 Al/1.7-2.3 Zn/bal. Mg

(liquidus/solidus temps 1110/830 F) (AWS-ASTM classification BMg-1)

3.3-4.7 Cu/9.3-10.7 Si/bal. Al

(liquidus/solidus temps 1085/970 F) (AWS-ASTM classification BAlSi-3)

In the table just given, constituents present at less than 1 part per hundred are not listed. U.S. Pat. No. 4,561,300 discloses a wide range of suitable materials having melting points between 76 C and 351 C. Examples include: COMPOSITION MELTING POINT (C.) Bi 48.5, In 41.5, Cd 10 076 In 52.34, Bi 47.66 088 Bi 52.5, Pb 32, Sn 15.5 096 Bi 54, Sn 26, Cd 20 103 Bi 67, In 33 110 In 52, Sn 48 118 Bi 56.5, Pb 43.5 126 Bi 56, Sn 40, Zn 4 133 Bi 60, Sn 40 139 Bi 60, Cd 40 147 Sn 68.35, Cd 29.25, Zn 2.4 159 Sn 71, Pb 24, Zn 5 170 Sn 67.75, Cd 32.25 175 Sn 62.5, Pb 36.15 180 Sn 61.9, Pb 38.1 184 Sn 91, Zn 9 198 Sn 91, Mg 9 205 Sn 95.8, Ag 3.5, Cu 0.7 218 Sn 96.5, Ag 3.5 222 Sn 99.5, Al 0.5 229 Sn 231 Sn 99.41, Cu 0.32, Al 0.27 234 Pb 79.7, Cd 17.7, Sb 2.6 239 Pb 84, Sb 12, Sn 4 243 Pb 82.6, Cd 17.4 249 Pb 88.9, Sb 11.1 253 Bi 97.3, Zn 2.7 256 Bi 97.5, Ag 2.5 263 Cd 82.6, Zn 17.4 265 Bi 273 Pb 91, Sb 4.68, Cd 4.32 276 Ga 92, Mg 18 285 Cd 92.45, Sb 7.55 294 Pb 96.97, Ag 2.20, Sb 0.83 301 Pb 97.5, Ag 2.5 303 Pb 97.55, Ag 1.75, Sn 0.7 311 Pb 98.1, Sb 1, Zn 0.9 315 Pb 97.4, Sn 2.6 320 Pb 98.76, Sn 1.24 325 Pb 329 Zn 92.97, Al 4.08, Mg 2.95 344 Te 70.6, Ag 29.4 351

Other suitable materials having a yield temperature over the range of 105 F to 357 F are commercially available from, for example, Cerro Metal Products Co. of Belefonte, Pa. Examples include: YIELD COMPOSITION TEMPERATURE (F.) 42.91 Bi/21.70 Pb/7.97 Sn/ 105 5.06 Cd/18.33 In/4.00 Hg 49.0 Bi/18.0 Pb/12.00 Sn/21.00 In 138 50.00 Bi/26.70 Pb/13.30 Sn/10.00 Cd 158 50.31 Bi/39.2 Pb/1.5 Sn/ 181 7.99 Cd/1.00 In 56.00 Bi/22.00 Pb/22.00 Sn 205 33.33 Bi/33.34 Pb/33.33 Sn 232 25.50 Bi/14.5 Pb/60.00 Sn 270 20.00 Bi/50.00 Pb/30.00 Sn 293 10.00 Bi/40.00 Pb/50.00 Sn 324 95.00 Bi/5.00 Sn 357

In the oil and gas industry, the invention will often be employed to form a seal in a tubing that extends generally downwardly into the earth. It may be desirable to remove standing liquids from the location where the plug is desired.

This can be done by the injection of gas at the wellhead. For example, the well can be bullheaded with nitrogen and the well liquids, if any, can be displaced to the perforations. Once the liquids have been removed, the invention can be carried out by positioning a platform for the molten metal in the tubing and forming a pool of the molten metal on the platform. A plastic bridge plug or other form of support such as a sand plug-back can provide a suitable platform. In a production tubing, the platform is preferably positioned slightly below a joint in the tubing, so that the molten material will flow into recesses which typically exist in the vicinity of the joints to more tightly secure the plug. In an annulus between the production tubing and the casing, the platform can be provided by the upper surface of the cement which fills the lower portion of the annulus. A column of high density particulates can also be placed ahead of eutectic material to adjust platform height or act as a bridging agent. The particulate prevents loss of the molten solder through incompetent tubing/casing packers or other leak paths. A column of high density particulate material, such as sand or barite, or iron or steel shot may also be positioned on top of the molten material, to maximize radial expansion of the material as it solidifies. Either column of particulate material or solder can be introduced into the well in dry-form or slurried in a liquid. If slurried, it can be placed in a dump bailer, through tubing, introduced at wellhead and allowed to free-fall to position, or by any other means of transport.

Referring now to FIG. 2, once the eutectic metal pellets are in place, igniter 40 is energized causing an exothermic reaction to occur in the exothermic reactant block 36. Sufficient heat is produced to melt the eutectic metal pellets 38 creating a molten mass. The remainder of exothermic heating apparatus 34′ not consumed in the exothermic reaction is then removed from the molten mass of eutectic metal. Additional pressure can be applied at the surface of well 18 to aid movement of molten metal into fissures within the casing, top of the cement plug, wellbore perforations, etc. The molten mass flows into cracks 30 and perforations 32 and is then allowed to solidify forming a sealing plug 44. Exothermic heating apparatus 34′ may optionally be withdrawn from well 18 before the plug solidifies

FIG. 3 shows an embodiment of a repair tool 50 which is used in place of the separate eutectic metal pellets and exothermic heating apparatus 34 of FIGS. 1 and 2. The configuration of well 18 again includes casing 20 located within subterranean formation 24. Also, a plug 26 is located in casing 20. Plug 26 may include include cracks 30 or need enhancement of seal capacity and casing 20 has perforations or other leak path 32.

Eutectic metal repair tool 50 includes a housing 52 comprising an outer annular chamber 54 filled with eutectic metal in form of pellets or a cast or machined annular ring 58 and an inner chamber 56 filled with an exothermic reactant material 60. Tool 50 also includes an igniter 62 for igniting exothermic material 60. A support line 64 is included to position tool 50 proximate cracks 30 and perforations 32 requiring sealing. Support line 64 may be tubing or else may be a wire line. Housing 52 includes a number of burst disks or release ports 64. Release ports 64 are filled with release plugs 66 which release when sufficient pressure and heat are produced as a result of igniting exothermic reactant material 60 and melting eutectic pellets.

Igniter 62 is activated igniting exothermic material 60 creating an exothermic reaction releasing large quantities of heat. Heat is absorbed through the walls of housing 52 melting eutectic pellets 58 and creating a molten mass of eutectic material. Heat and pressure are produced within housing 52 as a result of the igniting of exothermic material 60 melting eutectic pellets 58 and releasing release plugs 66. The molten mass of eutectic material exits release ports 64 and forms a pool molten metal atop plug 26. Similar to FIG. 2, a portion of the molten metal solidifies within cracks 30 and perforations 32 with the remainder of the molten mass forming a press fit seal (not shown in FIG. 3) within casing 20. Again, the end result will be similar to that of the plug formed in FIG. 2.

FIG. 4 illustrates another embodiment of a well 80 in a subterranean formation 82 wherein the present invention may be used to effect seals between structures of the well. A production casing 84 is held in a wellbore 86 by production cement 90. Similarly, an intermediate casing 92 is retained in wellbore 86 by intermediate cement 94. An inner annulus 96 is formed between production casing 84 and intermediate casing 92. An outer annulus 100 is created between intermediate casing 92 and wellbore 86. Eutectic metal pellets 102, 104 and 106 may be placed at any one of the bottom of wellbore 86, atop a cement or mechanical bridge plug placed anywhere within wellbore 86, adjacent the lower end of intermediate casing 92 in the inner annulus 96 and in outer annulus 100 or about a liner hanger or casing or tubing packer situated between two tubing. In this example, perforations 110 are shown which extend through production casing 84 and production cement 90.

Exothermic heating apparatus 34, as described above with respect to FIGS. 1 and 2, may then be used to heat any of the agglomerations of pellets 102, 104 and 106, depending on where a seal is desired to be formed. In the case of pellets 102 residing upon the bottom of the wellbore (or other similar support structure), exothermic heating apparatus 34 is positioned near the bottom of the wellbore prior to the introduction of pellets 102, as was the case with the embodiment shown in FIG. 1. As a result, heat rising from exothermic heating apparatus 34 melts pellets 102. Accordingly, a plug (not shown) is formed which seals production casing 84 and closes perforations 110.

With respect to pellets 104 and 106, exothermic heating apparatus 34 is placed generally adjacent the respective pellets 104 and 106 and the exothermic materials are ignited by igniter 40. Heat produced by the exothermic reaction then traverses production casing 84 and intermediate casing 92 and melts pellets 104 or 106 thus creating a eutectic plug (not shown). In FIG. 4, exothermic apparatus 34 is shown adjacent pellets 106. Again, the positioning of exothermic apparatus 34 will depend on where a seal plug is to be formed.

FIGS. 5 and 6 display another repair tool 120. In FIG. 5, repair tool 120 is being deployed through a tubing 122 and into a casing 124. In FIG. 6, eutectic metal repair tool 120 has been actuated to form a seal plug 126 with casing 124.

Referring to FIG. 5, eutectic metal repair tool 120 includes a slow burn pressure firing assembly 130, a lock down hydraulic dog assembly 132 with ears 134, a pair of rupture discs 136 and 140 sandwiching about an oxidizer cylinder 142, a dump bailer 144 and a petal basket 146 including petals 148. A firing tube 150 is telescopically mounted within a sliding sleeve 152. Eutectic metal pellets 154 are contained within dump bailer 144 intermixed with a hydrocarbon based material such as an oil or grease which serves as a fuel.

In operation, repair tool 120 is positioned within casing 124 as shown in FIG. 6. The lock down hydraulic dog assembly 132 is actuated causing ears 134 to engage and grip the inner surface of casing 124 locking tool 120 in place. Next, the slow bore pressure firing assembly 130 is activated causing rupture disks 136 and 140 to burst and an oxidizer within oxidizer cylinder 142 to discharge into dump bailer 144. The preferred oxidizer is bromium tri-fluoride. Those skilled in the art will appreciate that other oxidizers may also be used in place of the bromium tri-fluoride to provide oxygen to the fuel intermixed with the eutectic metal pellets 154. The combination of the oxidizer and fuel combusts melting eutectic metal pellets 154 into a molten mass. The molten mass is captured by extended petals 146 and solidified in situ to form seal plug 126.

While in the foregoing specification this invention has been described in relation to certain preferred embodiments thereof, and many details have been set forth for purposes of illustration, it will be apparent to those skilled in the art that the invention is susceptible to alteration and that certain other details described herein can vary considerably without departing from the basic principles of the invention. For example, fused chemical reactions could be adapted to work with any of the above embodiments. 

1. A method for creating a fluid seal in a subterranean well structure having a fluid seal defect, the method comprising: introducing a meltable repair material proximate a structure in a subterranean well which has a fluid seal defect or an isolating plug is desired; introducing exothermic reactant materials proximate the meltable repair material; igniting the exothermic reactant materials or otherwise initiating the exothermic reaction which supplies heat to and melts the meltable repair material into a molten mass; flowing the molten mass to contact the structure and fluid seal defect; and allowing the molten mass to solidify across the structure and the fluid seal defect to effect a fluid seal in the subterranean well structure.
 2. The method of claim 1 wherein: the exothermic reactant material includes thermite.
 3. The method of claim 1 wherein: the exothermic reactant material includes thermate.
 4. The method of claim 1 wherein: the exothermic reactant material includes bromine trifluoride.
 5. The method of claim 1 wherein: the exothermic reactant includes a fused chemical reaction.
 6. The method of claim 5 wherein: the fused chemical reaction includes using ammonium chloride and sodium nitrate as the exothermic reactant material and an acid catalyst acts as an igniter to initiate the exothermic reaction.
 7. The method of claim 1 wherein: the subterranean well structure which is repaired includes one of leaking cemented annuli or tubing packer or weak tubing hanger, leaking or potentially leaking plugs including cement and mechanical plugs, abandoned and unwanted perforations, high pressure intervals which are to be temporarily or permanently isolated, and gravel-packed production intervals which are to be shut-off from water influx.
 8. The method of claim 1 wherein: the meltable repair material is a solder.
 9. The method of claim 1 wherein: the meltable repair material is a eutectic metal.
 10. The method of claim 1 wherein: the meltable repair material is a eutectic metal which expands upon cooling and solidifying.
 11. The method of claim 1 wherein: the meltable repair material and the exothermic material are introduced within a single repair tool.
 12. The method of claim 1 wherein; the meltable repair material and the exothermic material are introduced sequentially proximate the structure to be repaired.
 13. A repair tool for effecting a fluid seal in a subterranean well structure having a fluid seal defect, the repair tool comprising: a housing containing a meltable repair material and an exothermic reactant material proximate the meltable repair material; wherein the housing may be introduced into a well and proximate a structure having a fluid seal defect and the exothermic reactant material may be ignited to melt the meltable repair material into a flowable molten mass which can be discharged from the housing to cool and solidify upon the structure to effect a fluid seal.
 14. The repair tool of claim 13 wherein: the meltable repair material includes at least one of a eutectic metal, a solder, a brazing material and a flux material to promote or increase adhesion.
 15. The repair tool of claim 13 wherein: the meltable repair material is eutectic metal which expands upon cooling and solidifiying from a molten state.
 16. The repair tool of claim 13 wherein: the exothermic reactant material is thermite.
 17. The repair tool of claim 13 wherein: the exothermic reactant material is thermate.
 18. The repair tool of claim 13 wherein: the exothermic reactant material includes ammonium chloride and sodium nitrite.
 19. The repair tool of claim 13 wherein: the housing includes a dump bailer and petal basket.
 20. The repair tool of claim 13 further comprising: an igniter to ignite the exothermic reactant material.
 21. The repair tool of claim 13 wherein: the exothermic reactant material includes an oxidizing agent and the repair meltable material includes a meltable metal and a hydrocarbon-based fuel; wherein the oxidizing agent and the hydrocarbon-based fuel may be combined and ignited to melt the meltable metal. 